DE2942322A1 - CLOCK - Google Patents

Abstract

A waterproof watch having a case and a base which are sealed in a water tight manner without the use of screw threads, is provided. The watch base is composed of a memory form alloy which may or may not be reversible. The watch base is deformed while in its Martensitic state and loosely fit adjacent a sealing portion of the case. The base is then permitted to rise above the Martensit/Austenit conversion temperature into its Austenitic state so that it returns to its undeformed shape and engages the sealing portion of the case in a water tight pressure fitting manner. The conversion temperature should be -20 DEG C. or below. A tubular conduit for the winding stem may also be composed of memory form alloy for sealing engagement with the case.

Description

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clock

The invention relates to watches, in particular wristwatches, and other devices with an interior of the device, e.g. B. the clockwork, comprehensive housing with at least one removable part, e.g. B. a bottom, is sealed watertight.

The production of guaranteed watertight watch cases (e.g. watertightness with external pressures of 3-20 bar) in technical watch production is difficult because the cutting of the customary, matching The fine thread in the back and case of the watches makes comparatively high technical demands. There is also the disadvantage that when cladding or after repairing the watch, the case back is firmly screwed onto the case or into the case must be screwed in and this can result in metal chips that lead to gait disturbances if they are in the clockwork arrive.

The object of the invention is a device, in particular a watch, with a housing and at least one, the housing, waterproof Closing part, which is brought into a detachable, watertight connection with the housing in a simpler manner can be.

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According to the invention, this goal is achieved in that the removable part of the housing is made of a shape memory alloy.

Such materials have long been z. B. from US-PS 3 · 012'882 and 3 · 174'851 and are known for various Purposes such as thermoelectric switches (e.g. DE-OS 2'724'255) and thermally resilient connecting elements in the form of pipe sleeves (e.g. DE-OS 2 * 065'65I).

The previously known technically significant uses of shape memory alloys are mainly based on one one-time use of the shape memory effect, for example in the sense as described in DE-OS 2'065'651 for pipe connection sleeves for the formation of permanent, d. H. practically insoluble, connections is described. In fact, the sudden change in shape of a structure made of shape memory alloy that has been mechanically "stressed" below the martensite / austenite transformation temperature, when heated above the transformation temperature and thereby occurring "relaxation", i. H. Return to the "memory form", mostly a so-called one-way effect that cannot be reversed by thermal means.

A thermal reversibility of the shape memory effect of corresponding alloys that is possible within certain limits - the so-called "two-way effect" - is z. B. from DE-OS 2'724'255 and can be used advantageously for special purposes, such as thermoelectric switches. However, the applicability of the shape memory effect for the formation of detachable connections could not be recognized from this.

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Surprisingly, it was found that shape memory alloys are also suitable for compounds which by their nature have to be detachable, such as the bottom of a watch case, even if only the one-way effect and not the thermally reversible two-way effect is the result is used. A more detailed explanation of the one-way or two-way effect can be found in DE-OS 2,724,255.

The invention is explained with reference to the accompanying drawings. Show it:

1 shows the semi-schematic sectional view of the fit of the housing and housing base in a first embodiment of the invention,

FIG. 2 shows a similar sectional view as in FIG. 1, but for the usual screw connection of the ground and housing,

3 shows the semi-schematic sectional representation of the fit of the intended for the assembly of the winding crown Part of a clock in the case and

4 shows the semi-schematic sectional illustration of the fit of the housing and housing base in a second embodiment of the invention.

The bottom end of the housing 11 of a wristwatch, shown semi-schematically in FIG. 1, comprises a clockwork (not shown) and is waterproof with a bottom 12 closed from shape memory alloy. To do this, a corresponding soil in a manner known per se, for. B. by machining, from a Ni / Ti or Ni / Ti / Cu or Cu / Al / Ni shape memory alloy, which is a martensite / auste-

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nit conversion ^{temperature of -20 0} C or below has prepared. The circumferential bead or edge 121 of the base 12 is provided with a conical undercut 122, which corresponds to a recess at the base-side end of the housing 11. Under normal conditions, ie in the austenitic state, the base 12 rests against the housing 11 with a watertight press fit. The base 12 is cooled to a temperature below the martensite / austenite transformation before it is attached to the housing and also below this Temperature deformed by stretching to such an extent that it can be placed loosely on the housing 11. The cooled and expanded base 12 is then placed on the housing 11 and allowed to warm to room temperature. When exceeded the martensite / austenite transition temperature takes the Bo The 12 returns to the shape it was in before the stretch (“Memory shape”) and lies against the housing 11 in a watertight manner.

To remove the bottom 12 from the housing 11, for. B. to repair the clock, the base 12 is filled with cooling liquid (e.g. Acetone / dry ice mixture) is cooled to a temperature below the transition temperature. If the bottom 12 is made of shape memory alloy with a two-way effect, it will jump when the temperature falls below the transition temperature, it returns to its expanded form and can simply be lifted off the housing 11.

However, if the base 12 is made of shape memory alloy with a one-way effect, there is one to lift off the housing relatively very little force required. To put it back on again, the base 12 is cooled down again to below the transition temperature, but no longer deformed, loosely applied to the housing 11 and warmed to room temperature. Again, if the conversion limit is exceeded,

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temperature achieved a watertight interference fit between the bottom 12 and the housing 11.

In Flg. 2 1st for comparison is a common catfish with the Bottom 22 screwed bottom end of a housing is shown. Apart from the fact that the thread has to be cut very precisely and there is a risk of a If there is chip formation, an additional sealing element, e.g. B. an In a corresponding annular recess 211 of the housing 21 inserted

O-ring 23 can be used. With a case back made

Shape memory adjustment can thus be dispensed with thread cutting, the formation of an annular groove and the inserted sealing element, which enables cost savings. Honing can also be simplified as a result.

There is no risk of chip formation when screwing.

In the case of a clock according to the invention, the The tubular part, the so-called "tube", which receives the crown shaft, is made of shape memory alloy. This is in Fig. 3 semi-schematically based on the housing part 31 placed in which the tubular crown shaft guide part 35 is used. Since the guide part 35 does not normally have to be removed to repair the watch, brings here the preferred use for the floor Shape memory alloy with two-way effect no special ren advantages. As for the connection between the housing and a watertight press fit is required for the part 35, a shape memory alloy part 35 to be assembled must after cooling to a temperature below the Martensite / austenite conversion only so far compressed that it will be in the following transgression this temperature applies to the housing 31 in a watertight interference fit.

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In Fig. 4 is again a semi-schematic GehMuseboden made of shape memory alloy - with one-way effect or, preferably, with two-way effect - in a watertight press fit solution in the bottom end of a housing 41, z. B. a watch case shown. The bottom 42 has a conical recess 422 and engages in a correspondingly shaped recess in the housing 41.

The insertion or removal of the base 42 into the housing 41 takes place in a similar way to that described in connection with FIG. 1, except that the first deformation of the base 42 after cooling below the martensite / austenite transformation temperature is here by compression or upsetting takes place and the watertight interference fit is achieved by expansion of the soil.

In general, the degree of deformation of the floor 12, 22 and 42 in the cooled, i.e. H. martensitic state when using shape memory alloys with one-way effect up to about 10% (compared to the corresponding dimension in austenitic state), when using shape memory alloys with a two-way effect, up to about 2%.

The temperature of the martensite / austenite transformation of shape memory alloys is usually not a sharply defined temperature point, but a temperature range of a few degrees Celsius. It is essential for the invention that this temperature or this temperature range is safely exceeded under the normally or intended ambient temperatures of the clock , so that an unintentional detachment of the bottom is excluded. Accordingly , the conversion of the martensitic to the

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BBC Baden

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Austenitic phase at temperatures of -20 C or above, ie at normal ambient temperatures, be completed. The transition temperature can, however, be considerably below this value. Only for practical reasons (availability of relatively trouble-free coolants, such as acetone / dry ice) of the range from -100 ⁰ C to -20 ⁰ C for the martensite / austenite transformation temperature of the shape memory alloy of the housing base is preferred.

Specific examples of suitable shape memory alloys are given below along with the respective temperatures the martensite-auseite conversion (Ms) given; all data in percent relate to weight.

15 20

alloy Ni Alloy composition in Ti 10 Cu Al % - Mn: - 1 MS 1 44 10 - other - Fe: - 1 -21 2 43 45 - - Fe: -25 3 55.3 46 , 7 - - Cr: -20 4th 55.4 44 , 6 10 - 1 -30 5 45 44 4th - 3 -20 6th 47 44 82, - -25 7th 3 46 82, , 75 14.5 -20 8th 3 - .6 14.4 -30 -

example

Of a shape memory alloy (44.6 wt.% Ti, 55.4% Ni, MS A -30 ⁰ C) was similar to a housing base for a men's wristwatch by machining with mating surfaces of the fabricated in Fig. 1 shown Art. The bottom end of the housing was also designed according to FIG. 1.

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The soil was cooled to about -80 ° C. in a mixture of acetone / CO ^ snow, widened at this temperature by about 3.5% on an expansion tool and placed on the housing. When heated over the conversion temperature jumped the bottom returned to its shape before stretching and formed a watertight seal on the case.

It goes without saying that within the scope of the invention, numerous There are possible variations. The alloy mentioned in the example can of course be replaced by other known ones Shape memory alloys are replaced. Furthermore, instead of stretching, the housing base can also be tensioned by compression if the mating surfaces of the housing and base accordingly, e.g. B. according to the schematic representation of Fig. 4 can be modified. The indicated in Figs. 1-4 indicated formations of the fitting surfaces with conical backs rotations can be modified to a large extent within the scope of professional knowledge, as long as the thermal Conversion of the tensioned martensite shape of the shape memory alloy into the austenite shape at the fit on the housing. occurring thrust or tensile forces are absorbed and made effective for a watertight press fit of the parts.

Furthermore, in a clock according to the invention, others can also Sealing parts are made of shape memory alloy besides the base and, like this, are connected to the housing in a watertight manner by utilizing the shape memory effect will; this also applies in particular to the part or parts of the housing which effect a watertight connection between the watch glass and the housing.

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Claims (8)

BBC Aktiengesellschaft., I63 / 78 Brown, Boveri & Cie. Baden (Switzerland) rit. I5.I2.78 claims 1. Clock / in particular wristwatch, with a clockwork encompassing Housing which is closed watertight with a removable bottom, characterized in that the bottom is made of a shape memory alloy. 2. Clock according to claim 1, in which the housing has a tubular, watertight part inserted into the housing for the watertight guidance of the elevator or
Has adjusting axis, characterized in that the
tubular part consists of a shape memory alloy. 3. Clock according to claim 1, characterized in that the shape memory alloy with a thermal
reversible shape memory effect is. 4. Clock according to one of the claims 1-3, characterized in that that the shape memory alloy is a martensite / austenite ter owns. sit / austenite transformation temperature at -20 C or below 5. Clock according to claim 4, characterized in that such a shape memory alloy is used, which contains nickel and titanium or nickel, titanium and copper or copper, aluminum and nickel as main components. 6. Device with a housing which is sealed watertight with at least one removable part, characterized in that that the removable part is made of a shape memory 030026/0670 ORIGINAL I63 / 78 nis alloy and is fitted in such a way that it is in the austenitic State of the shape memory alloy in a watertight press fit on the housing and in the martensitic State an oversize or undersize that allows the part to be removed from the housing. 7. Apparatus according to claim 6, characterized in that the martensite / austenite transition temperature of the Shape memory ter lies. Shape memory alloy in the range of -20 C or below 8. A method for the watertight closure of watches by connecting a housing that encompasses the movement with a case back, characterized in that the one made of a shape memory alloy with a martensite / Austenite transformation temperature of -20 C or below existing housing base in the martensite state is stretched or compressed to such an extent that it is in the martensite state loosely fits on or in the housing, and that the housing with loosely fitted or inserted Housing bottom in the expanded or compressed martensite state for sealing connection of the housing bottom with the housing to a temperature above the martensite / austenite transition temperature is brought. 030026/0576